Spine implant with an expandable cage and expandable vertebral attachment plate

ABSTRACT

A spine implant for receipt between and fastened to a lower vertebra and an adjacent upper vertebra is characterized by an expandable cage and an expandable plate attached to the expandable cage. When the expandable cage is expanded, both the expandable cage and the expandable plate expand together at a uniform rate of movement. Engagement features of the expandable cage cooperate with engagement features of the expandable plate such that expansion of the expandable cage carries the expandable plate along during its expansion. The engagement features of the expandable cage may be configured as notches, cavities, or recessed pockets, while the engagement features of the expandable plate may be configured as tangs, flanges, or protuberances styled to be received by the configured notches of the expandable cage. Cam locks on the expandable plate help bone fastener backout.

CROSS-REFERENCE TO RELATED PATENT APPLICATION

This patent application is a continuation of U.S. patent applicationSer. No. 17/181,058, now U.S. Pat. No. 11,457,957, filed on Feb. 22,2021, which claims benefit of and priority to U.S. ProvisionalApplication No. 63/008,690, filed on Apr. 11, 2020, the entiredisclosures of both are hereby incorporated by reference herein.

FIELD OF THE INVENTION

The present invention relates to implants for the spine and, moreparticularly, to expandable spine implants utilizing supplementalvertebral fixation for stabilizing adjacent vertebrae of the spine.

BACKGROUND OF THE INVENTION

Many people contend with spine issues due to age, disease, trauma,congenital, and acquired complications and conditions. While some spineissues can be alleviated without surgery, other spine issues necessitatesurgery. Spine issues such as decompression and stabilization can beaddressed with spine (vertebrae) fusion surgery. Spine fusion surgeryutilizes an intervertebral or interbody spine implant known as a cagebetween and attached to the affected adjacent vertebrae. Once disctissue has been removed from between the affected vertebrae, the cage isplaced within the disc space between the adjacent vertebrae. Bone graftmay be introduced into the cage for facilitating vertebral bone fusionand stopping movement between adjacent vertebrae. The cage is typicallyattached to the vertebrae by bone screws.

A desirable outcome of fusion surgery is the maintenance of height ofthe resulting anatomy relative to the original anatomy while providing astable and robust spine construct. Restoration of the height of theoriginal spine anatomy of the adjacent vertebrae maintains propervertebral spacing to help prevent nerve compression, restore andpreserve the natural alignment of the spine, and promote spinal fusion.Static (fixed height) or dynamic (adjustable height) cages may be usedin the intervertebral space. In the case of a static cage, a particularfixed height cage is used that approximates the original spine anatomy.In the case of a dynamic cage, the original spine anatomy can be betterapproximated. Because of variations in vertebral anatomy and otherissues, it is desirable for intervertebral spine implants (cages) to beadjustable in height (dynamic) rather than fixed in height (static).

Cages may be used alone (i.e. a stand-alone cage) or with supplementalvertebral attachment, such as a spine plate, for additional securementto the affected vertebrae. The spine plate may be dynamic or static. Thepositioning and securement of the spine implant (the cage and the plate)is important in order to approximate the original vertebral position ofthe individual and/or to achieve a desired position. It is oftendifficult during installation to adequately install a dynamic platerelative to a dynamic cage. Other problems may also be encounteredduring installation.

It is therefore desirous to have a spine implant for spinal fusion oftwo adjacent vertebrae that provides dynamic sizing. It is furtherdesirous to have a dynamic spine implant having an expandable spine cagefor receipt between a lower vertebrae and an adjacent upper vertebraeand an attached expandable spine plate for attachment to the upper andlower vertebrae for vertebral fusion.

SUMMARY OF THE INVENTION

A spine implant is characterized by an expandable cage and an expandableplate that, when connected to each other, expand/move/translate at auniform rate. This provides concerted alignment of the implant (cage andplate) to the adjacent vertebrae.

The expandable cage has engagement features that provide cooperationwith engagement features of the expandable plate. The expandable plateexpands with the expansion of the expandable cage at a uniform rate ofexpansion because the expandable plate is engaged with (connected to)the expandable cage. The expandable plate and expandable cage are alsoable to controllably collapse/contract/decrease in height at a uniformrate relative to one another. Once expanded however, the cage and platedo not collapse on their own. As shown in the figures, one non-limitingform of the engagement features of the expandable cage may be configurednotches, recesses, concavities or pockets (collectively, notches). Asalso shown in the figures, one non-limiting form of the engagementfeatures of the expandable plate are configured tangs, flanges, hooks,or protuberances (collectively, hooks) styled to cooperate with theconfigured notches or recessed pockets of the expandable cage.

With the engagement features providing continual engagement of theexpandable cage and expandable plate throughout expansion of theexpandable cage, the expandable cage also prevents collapsing of theexpandable plate under load. Thus, the expandable plate does not requirea secondary form of locking translation given its secured engagement tothe expandable cage.

The expandable plate will not be allowed to disengage from theexpandable cage during movement because during expansion, the engagementfeatures of the expandable plate will be captured between the vertebralbodies and the expandable cage, thus preventing migration.

A locking mechanism may be used to limit or stop movement (translation)of the expandable plate should the expandable plate be used withoutengaging with the expandable cage. In one form, a threaded lockingmember is inserted into the expandable plate and upon tightening thelocking member at a specific torque, a split pocket of the expandableplate that receives the locking member is cinched together, locking thealternate side of the expandable plate. Various methods may be used topermit and lock plate translation.

The expandable plate is configured to be attached to the lower vertebravia one or more bone fasteners, and to the upper vertebra via one ormore bone fasteners.

The spine implant may be used in an anterior lumbar interbody fusion(ALIF) procedure, with or as an anterior cervical plate system (ACPS),or for other spine applications.

Further aspects of the present invention will become apparent fromconsideration of the drawings and the following description of a form ofthe invention. A person skilled in the art will realize that other formsof the invention are possible and that the details of the invention canbe modified in a number of respects without departing from the inventiveconcept. The following drawings and description are to be regarded asillustrative in nature and not restrictive.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention and its features will be better understood byreference to the accompanying drawings, wherein:

FIG. 1 is a view of an expandable cage of the present spine implant, theexpandable cage in an unexpanded position/state;

FIG. 2 is another view of the expandable cage of FIG. 1 , the expandablecage in the unexpanded position;

FIG. 3 is an enlarged view of a front area of the expandable cage ofFIG. 1 ;

FIG. 4 is a front view of an expandable plate of the present spineimplant in an unexpanded position;

FIG. 5 is a rear view of the expandable plate of FIG. 4 in theunexpanded position;

FIG. 6 is a front view of the adjustable plate of FIG. 4 , theadjustable plate in an expanded position;

FIG. 7 is a view of a portion of the expandable cage in an unexpandedposition showing the expandable plate unengaged relative to theexpandable plate;

FIG. 8 is a view of the portion of the expandable cage of FIG. 7 withthe expandable plate engaged with the expandable cage, the expandableplate in an unexpanded position;

FIG. 9 is an enlarged view of the portion of the expandable cage of FIG.7 with the expandable plate engaged with the expandable cage, both ofwhich are in an unexpanded position;

FIG. 10 is a view of the expandable plate engaged with the expandablecage of the present spine implant, both of which are in an unexpandedposition;

FIG. 11 is a view of the expandable plate engaged with the expandablecage of the present spine implant, both of which are in an expandedposition;

FIG. 12 is a view of the expandable plate engaged with the expandablecage of the present spine implant, both of which are in an expandedposition;

FIG. 13 is a view of the expandable plate engaged with the expandablecage of the present spine implant, both of which are in an expandedposition;

FIG. 14 is a view of the expandable plate engaged with the expandablecage of the present spine implant, both of which are in an expandedposition, with bone screws received by the expandable plate;

FIG. 15 is a view of the expandable plate in an expanded position withbone screws received by the expandable plate;

FIG. 16 is a view of the expandable plate in an expanded position withbone screws received by the expandable plate;

FIG. 17 is a view of the expandable plate in an expanded position withbone screws received by the expandable plate and a threaded lockingmember shown in exploded view;

FIG. 18 is a view of the expandable plate in an expanded position withbone screws received by the expandable plate and a threaded lockingmember shown in exploded view;

FIG. 19 is a view of the expandable plate in an expanded position withbone screws received by the expandable plate and a threaded lockingmember received by the expandable plate; and

FIG. 20 is a view of the expandable plate in an expanded position withbone screws received by the expandable plate and a threaded lockingmember received by the expandable plate.

For the purposes of promoting an understanding of the principles of theinvention, reference will now be made to the embodiments illustrated inthe drawings and specific language will be used to describe the same. Itwill nevertheless be understood that no limitation of the scope of theinvention is thereby intended. Any alterations and further modificationsin the described embodiments, and any further applications of theprinciples of the invention as described herein are contemplated aswould normally occur to one skilled in the art to which the inventionrelates.

DETAILED DESCRIPTION OF THE INVENTION

FIGS. 7-14 depict various views of an expandable spine implant 10 foruse as a spine or spinal intervertebral (interbody) device preferably,but not necessarily, for use as part of an Anterior Lumbar InterbodyFusion (ALIF) procedure, as part of an Anterior Cervical Plate System(ACPS), lateral and cervical uses, and/or for other spine applications.The spine implant 10 is characterized by an expandable (and controllablycollapsible, but hereinafter “expandable”) cage 12 and an expandable(and controllably collapsible, but hereinafter “expandable”) plate 14.The expandable cage 12 and the expandable plate 14 are made from abio-compatible material such as, but not limited to, a metal (e.g.stainless steel, titanium, an alloy of stainless steel, an alloy oftitanium), and/or a plastic (e.g. medical grades of PVC andpolyethylene, PEEK, polycarbonate, Ultem PEI, polysulfone,polypropylene, polyurethane). The expandable cage 12 and expandableplate 14 may be made via various manufacturing processes known in theart. Both the expandable cage 12 and the expandable plate 14 arevertically (i.e. expandable and collapsible in a cranial/superior tocaudal/inferior direction) expandable (and controllably collapsible).

The expandable cage 12 sans the expandable plate 14 is shown in FIGS.1-3 . In general, the expandable cage 12 has a design overall similar inoverall functional attributes as described in US Patent Publication US2017/0367842 A1 (the '842 Publication), the entire contents of which isspecifically incorporated herein by reference, but with novel featuresthat define over the '842 Publication. The expandable cage 12 has afirst, lower, inferior, caudal, bottom part, portion, member or the like75 (collectively and hereinafter, lower member 75) and a second, upper,cranial, superior, or top part, portion, member or the like 74(collectively and hereinafter, upper member 74). The lower member 75 andthe upper member 74 are configured to mesh with one another, and theupper member 74 to move relative to the lower member 75 such that theoverall height of the spine implant 10 can increase (expand). The uppermember 74 can also decrease (contract/collapse) in height relative tothe lower member 75 in order to adjust and set a particular height ofthe spinal implant 10.

The lower member 75 is characterized by a generally rectangular base 100defining a first lateral side 101, and a second lateral side 102opposite the first lateral side 101, the nomenclature first and secondbeing arbitrary here, above and throughout unless specifically indicatedotherwise. As best seen in FIG. 12 , the base 100 preferably, but notnecessarily, has a serrated bottom 103 and a central hole 104. A frontportion 105 of the bottom 103 is preferably, but not necessarily,without serrations, being generally smooth. The front portion 105extends generally from the first lateral side 101 to the second lateralside 102. The base 100 also defines a rear 106 with an upstandinggenerally rectangular projection 107 situated between the first andsecond lateral sides 101, 102, the projection 107 forming a first area83 between a first lateral side (not labeled, but implicit) of theprojection 107 and the first lateral side 101, and a second area 82between a second lateral side (not labeled, but implicit) of theprojection 107 opposite the first lateral side of the projection 107,and the second lateral side 102. The projection 107 is shown disposedgenerally midway between the first and second lateral sides 101, 102,but may be positioned otherwise. The rear 106 may be configureddifferently than shown, such as having two or more projections. Theprojection 107 has a hole 108 that extends through the projection fromone side to the other. The hole 108 may be used for various purposes.

The base 100 also defines a front 112 opposite the rear 106 with anupstanding generally rectangular projection 109 situated between thefirst and second lateral sides 101, 102 that defines a first pocket 98between one side of the projection 109 and the first lateral side 101and a second pocket 99 between a second side of the projection 109 andthe second lateral side 102. The projection 109 is shown disposedgenerally midway between the first and second lateral sides 101, 102,but may be positioned otherwise. The front 112 may be configureddifferently than shown, such as having two or more projections. Theprojection 112 has a hole 108 that extends through the projection fromone side to the other. The hole 108 may be used for various purposessuch as allow access to a socket thereof for manipulating the cagemovement (expansion/contraction) mechanism 88. A notch, cutout, cavity,depression or the like 111 is provided in the front of the front portion105, at the bottom of the projection 109. The notch 111 provides anengagement feature for receipt of an engagement feature of theexpandable plate 14, particularly the lower or first portion or member16, for the base 100. The notch 111 is configured to receive and/orengage with an engagement feature (e.g. hook) of the expandable spineplate 14 and, particularly, the configured hook 65 extending from thebackside 67 of the first portion 16 of the expandable plate 14. Thenotch 111 holds the hook 65 of the first portion 16 so that the firstportion 16 does not move with respect to the base 100 of the expandablecage 12.

The upper member 74 of the expandable cage 12 is characterized by agenerally rectangular body 115 having a top 76 with serrations or thelike covering its majority with the exception of a front strip or area92 at the front of the body 115 that extends from the first lateral side77 to the second lateral side 78, a first lateral side 77, a secondlateral side 78 opposite the first lateral side 76, the nomenclaturefirst and second being arbitrary, a front that is generally divided intoa first front portion 79 a proximate the first lateral side 77 and asecond front portion 79 b proximate the second lateral side 78, and arear defined by a first flange 83 situated proximate to the firstlateral side 77 and a second flange 82 situated proximate the secondlateral side 78. The first flange 83 is sized for reception in the firstarea 83 of the base 100, while the second flange 82 is sized forreception in the second area 82 of the base 100. The first area 83provides a channel for reception and movement therein of the firstflange 83, while the second area 82 provides a channel for reception andmovement therein of the second flange 82, such that the upper member 74is axially moveable up and down in and relative to the lower member 75.An area 93 is defined between the first front portion 79 a and thesecond front portion 79 b of the upper member 74 that is sized andconfigured to receive the flange 109 of the lower member 75.

The upper member 74 further includes a first front nook, cutout, cavityor the like 80 disposed at a first lateral end (not labeled) of thefirst front portion 79 a proximate the first lateral side 101 of thebase 100, and a second front nook, cutout, cavity or the like 81disposed at a second lateral end (not labeled) of the second frontportion 79 b proximate the second lateral side 102 of the base 100. Thefront end of the first lateral side 101 is configured to allow access tothe first front nook 80, while the front end of the second lateral side102 is configured to allow access to the second front nook 81. The firstand second nooks 80, 81 are used to receive an installationinstrument/tool (not shown) to aid in implanting/placement of theexpandable cage 12.

The upper member 74 further includes engagement features for theexpandable plate 14, particularly the second or upper portion 15 of theexpandable plate 14. A first notch, cutout, cavity, depression or thelike 95 is provided in the top of the strip 92 at the intersecting edgeof the strip 92 and the first front portion 79 a proximate to one sideof the area 93. A second notch, cutout, cavity, depression or the like94 is provided in the top of the strip 92 at the intersecting edge ofthe strip 92 and the second front portion 79 b proximate to another sideof the area 93. The first and second notches 95, 94 provides a spineplate engagement feature for the upper member 74. The first and secondnotches 95, 94 are configured to receive and/or engage with engagementfeatures of the expandable plate 14 and, particularly and respectively,with a first configured hook 39 extending from a backside 29 of thesecond portion 15 of the expandable plate 14, and a second configuredhook 38 extending from the backside 29 of the second portion 15 of theexpandable plate 14. As illustrated in FIGS. 7-9 , the notches 95, 94hold the hooks 39, 38 of the second or upper plate portion or member 15so that the second plate portion 15 does not move with respect to thelower or first plate portion or member 14.

As best seen in FIGS. 1-3, 7-8, and 12 , the movement or drive structure88 for expanding and contracting the expandable cage 12 will now bedescribed, but reference is made to the '842 Publication for a manner ofachieving cage expansion and contraction, which can be used for thepresent expandable cage 12 and, explains in greater detail how thepresent movement structure 88 works in like manner thereto. The body 115of the upper portion 74 of the expandable cage 12 includes a middlesection 87 extending from the front to the rear of the body 115. Themiddle section 87 defines a first opening 85 at one lateral side of themiddle section 87, and a second opening 86 at an opposite lateral sideof the middle section. The openings in the upper and lower members 74,75 aid, promote and/or assist in bone ingrowth with or without bonegraft. The middle section 87 maintains the movement structure 88 thatallows for axial movement between the upper member 74 and the lowermember 75 to cause the expandable cage 12 to expand and collapse(contract).

A first rotation element 90 is provided at the front of the middlesection 87, while a second rotation element 91 is provided at the rearof the middle section 87. A threaded shaft 89 connects the first andsecond rotation elements 90, 91. The threaded shaft 89 is accessible viathe hole 108 of the flange 107 of the lower member 75. Rotation of thethreaded shaft 89 causes the first and/or second rotation elements 90,91 to move (raise/expand and lower/contract) the upper member 74relative to the lower member 75. FIGS. 1 and 2 , e.g., show theexpandable cage 12 only, with the upper member 74 thereof in anon-expanded or un-raised position relative to the lower member 75thereof. FIGS. 11-14 , e.g., show the expandable cage 12 in an expandedor raised position relative to the lower member 75. The expandable plate14 is also shown in FIGS. 11-14 , e.g., connected to the expandable cage12 via the hooks 38, 39 of the second portion 15 engaging the notches94, 95 of the upper member 74 of the expandable cage 12, and the hook 65engaging the notch 111 of the lower member 75 of the expandable cage 12.

The expandable plate 14 is shown in FIGS. 4-6 . In general theexpandable plate 14 has a design that is overall similar, but not thesame, in overall functional attributes as described in US PatentPublication US 2017/0215930 A1, the entire contents of which isspecifically incorporated herein by reference—but with novel featuresthat define the expandable plate 14 over the '930 Publication. In FIG. 4, the expandable plate 14 is shown in a non-expanded position and fromthe front thereof. In FIG. 5 , the expandable plate 14 is shown in anon-expanded position and from the back thereof. In FIG. 6 , theexpandable plate 14 is shown from the front in an expanded positionwherein the first and second portions 15, 16 are separated from eachother.

The expandable plate 14 has a second portion, segment, member, part,component or the like 15 and a first portion, segment, member, part,component or the like 16, the second portion 15 may be considered anupper portion while the first portion 16 may be considered a lowerportion, the upper portion 15 configured for engagement with the uppermember 74 of the expandable cage 12, and the lower portion 16 configuredfor engagement with the lower member 75 of the expandable cage 12.

The second portion 15 is configured for attachment to vertebral bone ofan upper vertebra (not shown) and is characterized by a generally flatbody 40 defining a generally flat front 18, a generally flat rear 19,and a curved top 20. A first boss 21 is formed at a first top cornerwhile a second boss 25 is formed at a second top corner opposite thefirst top corner. A first boss bore 22 extends through the first boss 21and is configured for reception and retention of a bone screw 150. Thefirst boss bore 22 includes internal threading 24 for meshing with thethreading 155 about the underside of the head 151 of the bone screw 150.A countersink 23 is provided in the front 18 surrounding the first bossbore 22 for reception of the bone screw head 151. In order to aid and/orassist in retaining the bone screw 150 in the first boss bore 22, and/orto prevent or inhibit bone screw back-out, a locking member 33 isprovided in a hole 32 in the front 18 of the second portion 15 adjacentthe first boss bore 22. The locking member 33 is rotatable in the hole32 via an instrument or tool (not shown) that is received in aconfigured socket (as seen in the Figures) of the locking member 33. Thelocking member 33 is generally round with a flat 34 on one side thereof.The hole 32 and thus the locking member 33 are closely adjacent thefirst boss bore 22 and thus the head 151 of a bone screw 150. When thelocking member 33 is rotated such that the flat 34 is adjacent the firstboss bore 22 and thus adjacent the head 151 of a bone screw 150, (see,e.g. FIG. 20 ), the head 151 and thus the bone screw 150 can freely passby the locking member 33. This allows the bone screw 150 to be removedfrom the first boss bore 22 or received in the first boss bore 22. Whenthe flat 34 is rotated away from the first boss bore 22 and thus thehead 151 of the bone screw 150, the head of the locking member 33extends over the head 151 of the bone screw 150 such the head 151 andthus the bone screw 150 cannot freely pass by the locking member 33 andout of the first boss bore 22. This locks the bone screw 150 in placerelative to the second portion 15.

A second boss bore 26 extends through the second boss 25 and isconfigured for reception and retention of a bone screw 150. The secondboss bore 26 includes internal threading 28 for meshing with thethreading 155 about the underside of the head 151 of the bone screw 150.A countersink 27 is provided in the front 18 surrounding the second bossbore 26 for reception of the bone screw head 151. In order to aid and/orassist in retaining the bone screw 150 in the second boss bore 26,and/or to prevent or inhibit bone screw back-out, a locking member 36 isprovided in a hole 35 in the front 18 of the first portion 15 adjacentthe second boss bore 26. The locking member 36 is rotatable in the hole35 via an instrument or tool (not shown) that is received in aconfigured socket (as seen in the Figures) of the locking member 36. Thelocking member 36 is generally round with a flat 37 on one side thereof.The hole 35 and thus the locking member 36 are closely adjacent thesecond boss bore 26 and thus the head 151 of a bone screw 150. When thelocking member 36 is rotated such that the flat 37 is adjacent thesecond boss bore 26 and thus adjacent the head 151 of a bone screw 150,(see, e.g. FIG. 20 ), the head 151 and thus the bone screw 150 canfreely pass by the locking member 36. This allows the bone screw 150 tobe removed from the second boss bore 26 or received in the second bossbore 26. When the flat 37 is rotated away from the second boss bore 26and thus the head 151 of the bone screw 150, the head of the lockingmember 36 extends over the head 151 of the bone screw 150 such the head151 and thus the bone screw 150 cannot freely pass by the locking member36 and out of the second boss bore 26. This locks the bone screw 150 inplace relative to the second portion 15.

Axially opposite the curved top 20 of the second portion 15 is a firstlateral leg 29 and a second lateral leg 30 each extending axiallydownward relative to the first and second bosses 21, 25. The first andsecond lateral legs 29, 30 define a notch, cavity, depression, channelor the like 31 between their laterally inside/inner surfaces (oppositethe outer. The channel 31 creates an inner track for reception of atleast a part of the first portion 16 as the first and second portions16, 15 move or expand relative to one another. A first configured hook,tang, flange or the like 38 extends outwardly (transverse) from the rearsurface 19 of the second portion 15 and is configured for reception inthe notch 94 of the upper portion 74 of the expandable cage 12. A secondconfigured hook, tang, flange or the like 39 extends outwardly(transverse) from the rear surface 19 of the second portion 15 and isconfigured for reception in the notch 95 of the upper portion 74 of theexpandable cage 12.

The first portion 16 is configured for attachment to vertebral bone of alower vertebra (not shown) and is characterized by a generally flat body41 defining a generally flat front 66, a generally flat rear 57, and acurved bottom 42. A third configured hook, tang, flange or the like 65extends outwardly (transverse) from the rear surface 67 of the firstportion 16 and is configured for reception in the notch 111 of the lowerportion 75 of the expandable cage 12. A third boss 51 is formed at afirst bottom corner of the second portion 16 while a fourth boss 55 isformed at a second bottom corner opposite the first bottom corner. Athird boss bore 52 extends through the third boss 51 and is configuredfor reception and retention of a bone screw 150. The third boss bore 52includes internal threading for meshing with the threading 155 about theunderside of the head 151 of the bone screw 150. A countersink 53 isprovided in the front 66 surrounding the third boss bore 52 forreception of the bone screw head 151. In order to aid and/or assist inretaining the bone screw 150 in the third boss bore 52, and/or toprevent or inhibit bone screw back-out, a locking member 63 is providedin a hole 62 in the front 66 of the second portion 16 adjacent the thirdboss bore 52. The locking member 63 is rotatable in the hole 62 via aninstrument or tool (not shown) that is received in a configured socket(as seen in the Figures) of the locking member 63. The locking member 63is generally round with a flat 64 on one side thereof. The hole 62 andthus the locking member 63 are closely adjacent the third boss bore 52and thus the head 151 of a bone screw 150. When the locking member 63 isrotated such that the flat 64 is adjacent the third boss bore 52 andthus adjacent the head 151 of a bone screw 150, (see, e.g. FIG. 20 ),the head 151 and thus the bone screw 150 can freely pass by the lockingmember 63. This allows the bone screw 150 to be removed from the thirdboss bore 52 or received in the third boss bore 52. When the flat 64 isrotated away from the third boss bore 52 and thus the head 151 of thebone screw 150, the head of the locking member 63 extends over the head151 of the bone screw 150 such the head 151 and thus the bone screw 150cannot freely pass by the locking member 63 and out of the third bossbore 52. This locks the bone screw 150 in place relative to the firstportion 16.

A fourth boss bore 56 extends through the fourth boss 55 and isconfigured for reception and retention of a bone screw 150. The fourthboss bore 56 includes internal threading 58 for meshing with thethreading 155 about the underside of the head 151 of the bone screw 150.A countersink 57 is provided in the front 66 surrounding the fourth bossbore 56 for reception of the bone screw head 151. In order to aid and/orassist in retaining the bone screw 150 in the fourth boss bore 56,and/or to prevent or inhibit bone screw back-out, a locking member 60 isprovided in a hole 59 in the front 66 of the second portion 16 adjacentthe fourth boss bore 56. The locking member 60 is rotatable in the hole59 via an instrument or tool (not shown) that is received in aconfigured socket (as seen in the Figures) of the locking member 60. Thelocking member 60 is generally round with a flat 61 on one side thereof.The hole 59 and thus the locking member 60 are closely adjacent thefourth boss bore 56 and thus the head 151 of a bone screw 150. When thelocking member 60 is rotated such that the flat 61 is adjacent thefourth boss bore 56 and thus adjacent the head 151 of a bone screw 150,(see, e.g. FIG. 20 ), the head 151 and thus the bone screw 150 canfreely pass by the locking member 60. This allows the bone screw 150 tobe removed from the fourth boss bore 56 or received in the fourth bossbore 56. When the flat 61 is rotated away from the fourth boss bore 56and thus the head 151 of the bone screw 150, the head of the lockingmember 60 extends over the head 151 of the bone screw 150 such the head151 and thus the bone screw 150 cannot freely pass by the locking member60 and out of the fourth boss bore 56. This locks the bone screw 150 inplace relative to the first portion 16.

Axially opposite the curved bottom 42 of the second portion 16 is a topflange 43 defining a first lateral notch 44 on a first lateral side ofthe top flange 43, and a second lateral notch 45 on a second lateralside of the top flange 43 opposite the first lateral notch 45. Theflange 43 is sized and/or configured for sliding reception in the notch31 of the second portion 15. The first lateral notch 44 is sized andconfigured for sliding receipt of the first lateral leg 29 of the secondportion 15. The second lateral notch 45 is sized and configured forsliding receipt of the second lateral leg 30 of the second portion 15.The first lateral notch 44 may include a movement feature 71, shown as aslot or protrusion, for the first lateral leg 29 of the second portion15. The first lateral leg 29 may include like and/or complementaryfeatures. The second lateral notch 45 may includes a movement feature70, shown as a slot or protrusion for the second lateral leg 30 of thesecond portion 15. The second lateral leg 30 may include like and/orcomplementary features. The flange 30 is shown to include a central bore71 with a countersink 49 formed around the central bore 71. A firstinset 47 is formed adjacent an upper area of the central bore 71 while asecond inset 48 is formed adjacent a lower area of the central bore.

FIGS. 11-12 show the expandable plate 14 connected to the expandablecage 12 and in an expanded state. In FIG. 7 , the expandable cage 12 hasnot been expanded so that the hooks 38, 39 of the second portion 15 ofthe expandable plate 14 have not been received in the notches 94, 95 ofthe upper section 74 of the expandable cage 12. In FIG. 8 , the hooks38, 39 of the second portion 15 of the expandable plate 14 have beenreceived in the notches 94, 95 of the upper section 74 of the expandablecage 12. FIG. 10 shows an un-expanded cage 12 and an un-expanded plate14. The various figures show the expandable cage 12 and the expandableplate 14 in expanded and un-expanded positions.

FIGS. 14-20 show the spine implant 10 with bone screws 150 for attachingthe expandable plate 14 to vertebral bone of adjacent upper and lowervertebrae (not shown). The bone screws 150 shown are all the same.However, other types and/or shapes of bone screws may be used.

The bone screw 150 is formed of a suitable biocompatible material suchas those of the expandable cage 12 and the expandable plate 14 asdescribed above, and is made in a same or similar manner. The bone screw150 is characterized by a threaded shaft 153 having a head 151 at oneend of the threaded shaft 153 and a generally pointed tip 154 at anopposite end of the threaded shaft. The head 151 includes a socket orhole 152 configured to receive an installation tool (not shown) having acomplementary portion that is received in the socket 122. The undersideof the head 151 has external threading that is configured to mesh withthe threading of the bone screw holes of the expandable plate 14.

The connection member 120 (shown herein as, but not limited to, aconnecting or connection screw 120) is best seen in FIGS. 17-18 . Theconnection screw 120 is formed of a suitable biocompatible material suchas those of the cage 12 and the plate 14 as described above, and is madein a same or similar manner. The connection screw 120 provides onemanner of connecting or joining the plate 14 to the cage 12. Theconnection screw 120 has a threaded shaft 123 of a generally cylindricalshape, with a head 121 at one end of the threaded shaft 123, and a tip124 at an opposite end of the threaded shaft 123. The tip 124 isgenerally flat. The threaded shaft 123 is sized and configured forreception in the threaded bore 46 of the top/flange 43 of the firstportion 16 of the expandable plate 14. The head 121 includes a socket orhole 122 configured to receive an installation tool (not shown) having acomplementary portion that is received in the socket 122.

While the invention has been illustrated and described in detail in thedrawings and foregoing description, the same is to be considered asillustrative and not restrictive in character, it being understood thatonly the preferred embodiments have been shown and described and thatall changes and modifications that come within the spirit of theinventions are desired to be protected. It should be understood thatwhile the use of words such as preferable, preferably, preferred or morepreferred utilized in the description above indicate that the feature sodescribed may be more desirable, it nonetheless may not be necessary andembodiments lacking the same may be contemplated as within the scope ofthe invention, the scope being defined by the claims that follow.

What is claimed is:
 1. A spine implant for use between a lower vertebradefining a lower vertebra outer diameter and an adjacent upper vertebradefining an upper vertebra outer diameter, the spine implant comprising:an expandable intervertebral cage having a first component and a secondcomponent movable relative to the first component, the first componenthaving a first engagement feature, the second component having a secondengagement feature; and an expandable vertebral mounting plate having afirst segment defining a first front surface and a first rear surface,and a second segment defining a second front surface and a second rearsurface and movable relative to the first segment, the first segmenthaving a first engagement feature configured to engage with the firstengagement feature of the first component, the second segment having asecond engagement feature configured to engage with the secondengagement feature of the second component, the first segment furtherhaving a first bone screw bore extending from the first front surface tothe first rear surface, the first bone screw bore configured to receivea bone screw that mounts the first segment to the lower vertebra byabutment of the first rear surface of the first segment to the lowervertebra outer diameter, and the second segment further having a secondbone screw bore extending from the second front surface to the secondrear surface, the second bone screw bore configured to receive a bonescrew that mounts the second segment to the upper vertebra by abutmentof the second rear surface of the second segment to the upper vertebraouter diameter; whereby the expandable intervertebral cage and theexpandable vertebral mounting plate move as the expandableintervertebral cage is expanded.
 2. The spine implant of claim 1,wherein the first engagement feature of the first component is disposedin a bottom of the first component, wherein the second engagementfeature of the second component is disposed in a top of the secondcomponent, and wherein the second component comprises a third engagementfeature disposed in the top of the second component.
 3. The spineimplant of claim 1, wherein the first engagement feature of the firstcomponent of the expandable intervertebral cage comprises a firstrecess, and the first engagement feature of the first segment of theexpandable vertebral mounting plate comprises a first hook.
 4. The spineimplant of claim 1, wherein the second engagement feature of the secondsegment of the expandable vertebral mounting plate is situated proximateto a first lateral side of the second segment of the expandablevertebral mounting plate, and wherein the second segment comprises athird engagement feature disposed proximate to a second lateral side ofthe second segment of the expandable vertebral mounting plate.
 5. Thespine implant of claim 4, wherein the second engagement feature of thesecond component of the expandable intervertebral cage comprises asecond recess, the third engagement feature of the second component ofthe expandable intervertebral cage comprises a third recess, the secondengagement feature of the second segment of the expandable vertebralmounting plate comprises a second hook, and the third engagement featureof the second segment of the expandable vertebral mounting platecomprises a third hook.
 6. The spine implant of claim 1, wherein thefirst segment of the expandable vertebral mounting plate has a bore forreceiving an attachment member for connecting the first segment of theexpandable vertebral mounting plate to the first component of theexpandable intervertebral cage.
 7. The spine implant of claim 1, whereinthe first engagement feature of the first segment of the expandablevertebral mounting plate is situated between a first lateral side of thefirst segment of the expandable vertebral mounting plate and a secondlateral side of the first segment of the expandable vertebral mountingplate.
 8. The spine implant of claim 1, further comprising a manuallyoperated mechanism for vertically displacing the first component of theexpandable intervertebral cage relative to the second component of theexpandable intervertebral cage.
 9. The spine implant of claim 1, furthercomprising: a first cam lock situated in the first segment of theexpandable vertebral mounting plate adjacent the first bone screw boreand configured to selectively prevent a first bone screw received in thefirst bone screw bore from backing out of the first bone screw bore; anda second cam lock situated in the second segment of the expandablevertebral mounting plate adjacent a third bone screw bore and configuredto selectively prevent a third bone screw received in the third bonescrew bore from backing out of the third bone screw bore.
 10. A spineimplant comprising: an expandable intervertebral cage for implantationbetween a lower vertebra defining a lower vertebra outer diameter and anadjacent upper vertebra defining an upper vertebra outer diameter of aspine, the expandable intervertebral cage having a first component and asecond component movable with respect to the first component, and adisplacement mechanism situated between the first component and thesecond component, the displacement mechanism operative to move thesecond component relative to the first component, the first componenthaving a first recess and the second component having a second recess;and an expandable vertebral mounting plate for attachment to the uppervertebra outer surface, the lower vertebra outer surface, and theexpandable intervertebral cage, the expandable vertebral mounting platehaving a first plate segment and a second plate segment, the first platesegment and the second plate segment movable relative to one another toprovide a separation between the first plate segment and the secondplate segment, the first plate segment having a first hook configuredfor reception in the first recess of the first component and the secondplate segment having a second hook configured for reception in thesecond recess of the second component, the first plate segment furtherhaving a first bone screw bore extending through the first plate segmentand configured to receive a bone screw that mounts the first platesegment to the lower vertebra by abutment of the first plate segment tothe lower vertebra outer diameter; whereby the expandable intervertebralcage and the expandable vertebral mounting plate move as the expandableintervertebral cage is expanded.
 11. The spine implant of claim 10,wherein the first recess of the first component is disposed in a bottomportion of the first component adjacent a front of the first component,and wherein the second recess of the second component is disposed in atop portion of the second component adjacent a front of the secondcomponent.
 12. The spine implant of claim 11, wherein the first hook ofthe first plate segment of the expandable vertebral mounting plate issituated between a first lateral side of the first plate segment and asecond lateral side of the first plate segment.
 13. The spine implant ofclaim 12, wherein the second hook of the second plate segment of theexpandable vertebral mounting plate is situated proximate to a firstlateral side of the second plate segment.
 14. The spine implant of claim10, wherein the first plate segment comprises a second bone screw boreextending through the first plate segment, wherein the first bone screwbore is proximate a first lateral side of the first plate segment andthe second bone screw bore is proximate a second lateral side of thefirst plate segment.
 15. The spine implant of claim 14, wherein thefirst plate segment includes a first plate flange between the first bonescrew bore and the second bone screw bore, the first plate flangeextending upward from the first plate segment.
 16. A spine implant foruse between a lower vertebra defining a lower vertebrae outer diameterand an adjacent upper vertebra outer diameter, the spine implantcomprising: an expandable intervertebral cage comprising: a firstcomponent having a first recess, a second component movable relative tothe first component and having a second recess, and a displacementmechanism situated between the first component and the second component,the displacement mechanism operative to move the second componentrelative to the first component; and an expandable vertebral mountingplate for attachment to the upper vertebra outer surface, the lowervertebrae outer surface, and the expandable intervertebral cage, theexpandable vertebral mounting plate comprising: a first plate segment,the first plate segment having a first hook configured for reception inthe first recess of the first component, a second plate segment, thefirst plate segment and the second plate segment movable relative to oneanother to provide a separation between the first plate segment and thesecond plate segment, the second plate segment having a second hookconfigured for reception in the second recess of the second component,the second plate segment further having a first bone screw boreextending through the second plate segment and configured to receive abone screw that mounts the second plate segment to the upper vertebra byabutment of the second plate segment to the upper vertebrae outerdiameter, whereby the expandable intervertebral cage and the expandablevertebral mounting plate move as the expandable intervertebral cage isexpanded.
 17. The spine implant of claim 16, wherein the second platesegment comprises a second bone screw bore extending through the secondplate segment, wherein the first bone screw bore is proximate a firstlateral side of the second plate segment and the second bone screw boreis proximate a second lateral side of the second plate segment.
 18. Thespine implant of claim 17, wherein the second plate segment comprises afirst lateral leg and a second lateral leg, the first lateral legsituated proximate the first bone screw bore and extending downward fromthe first bone screw bore, and the second lateral leg situated proximatethe second bone screw bore and extending downward from the second bonescrew bore.
 19. The spine implant of claim 18, wherein the first lateralleg and the second lateral leg define a recess between the first lateralleg and the second lateral leg.
 20. The spine implant of claim 19,wherein the recess between the first lateral leg and the second lateralleg is configured for reception of a flange of the first plate segment.